Archery bow sight

ABSTRACT

An optical bow sight which can be accessorized with an adjustable range sighting pin or torque and cant compensation or both of these features, but is fully functional without either accessory. The optical sight has a shrouded array of fiber optics sight pins which are removable from the sight housing with their support as a single unit. The sight pins are clad in a metallic glass because of the corrosion resistance of such materials. Light collected over a wide field falls on segments of the sight pin fibers coiled in the housing of the optical unit or falls on a trap which redirects the light onto the fiber segments. A lens may optionally be employed to promote the collection of ambient light, and a shutter or variable size aperture may be provided to control the light reaching the sight pin fibers. An elastomeric damper can be advantageously mounted on the sight to minimize accuracy effecting shock and/or vibration, and a level bubble may be provided to aid in avoiding cant of the bow to which the sight is mounted.

CROSS-REFERENCE TO A RELATED APPLICATION

Applicants are entitled to and hereby claim, the priority of provisionalapplication No. 60/879,944 filed 10 Jan. 2007.

TECHNICAL FIELD OF THE INVENTION

The present invention relates to novel, improved, archery bow sights.

BACKGROUND OF THE INVENTION

A common type of archery bow sight employs a set of vertically-spacedapart sight pins, each corresponding to a different range (distance to atarget). These pins are installed in a frame which is mounted to theriser of the bow.

In low-light conditions, those ends of the pins used for sighting can bedifficult to see clearly, if at all. Accordingly, it has been proposedthat the sighting ends of the pins be illuminated.

One approach that has been suggested involves the use of fiber optics toilluminate the sighting ends of the pins. Sights of that character aredisclosed in U.S. Pat. Nos. 5,435,068 issued 25 Jul. 1995 to Thames, etal., and 7,082,690 issued 1 Aug. 2006 to Knoshnood.

SUMMARY OF THE INVENTION

There have now been invented and disclosed herein new and novel bowsights which likewise employ fiber optics, but have a number ofsignificant features and advantages which are not possessed bypreviously proposed, fiber optics bow sights.

One such feature is a light collecting system which gathers light over awide hemispherical field and thereby significantly increases the amountof light that can be transmitted to the sighting ends of the pins, whichare the terminal segments of optical fibers. This makes those endsreadily visible under even extremely poor lighting conditions. That thesight provides bright, easily seen aiming points when the ambient lightis poor is significant because a number of jurisdictions do not allowartificial light to be used in hunting game.

A companion feature of the sights disclosed herein is that the opticalfibers are side-loaded as well as end-loaded. This significantlyincreases the efficiency with which light can be loaded into the fibers.Also, maximizing fiber optic loading reduces the needed lengths of thefibers, which is advantageous from the viewpoints of cost,manufacturability, and serviceability.

A second, related feature is a novel light trap for the collected light.The light trap redirects the collected light onto the optical fibers andalso makes a significant contribution to the efficiency of the sight.

Another important feature of the present invention is the encapsulationof the exposed optical fiber segments constituting the sighting pins ina metallic glass such as one of those available from LiquidmetalTechnologies. These materials are extremely resistant to corrosion,which is a common problem, particularly in the sights of hunting bows.Metallic glasses may be lighter than competing materials such as steel,have considerable flexibility, and are readily molded.

Yet another feature of the present invention is a novel modularconstruction which allows a fully functional basic sight to be upgradedto provide additional features. One module adds an adjustable sightingpin for more distant ranges to the sight. Another add-on providesadjustable torque and cant compensation for the bow on which the sightis mounted.

Also significant is the attachment of elastomeric dampers akin to thosedisclosed in U.S. Pat. No. 5,362,046 issued Nov. 8, 1994, to Sims to thesight at strategic locations. These dampers significantly reduce shockand vibration loads imposed on the sight when the bow is fired,contributing to accuracy and increased service life of the sight,reducing the sound made when the bow is fired, and reducing thepossibility of shock and vibration knocking the sight out of alignment.

It is another feature of the invention that the sighting pins andsupporting frame are removable from the installable in the sight as asingle unit. This is important from the viewpoints of manufacturabilityand serviceability. Also, this feature makes it convenient for thearcher to use interchangeable sight pin units to optimize the bow fordifferent poundage settings and arrow weights.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of the compound bow equipped with a bow sightwhich is constructed in accord with, and embodies, the principles of thepresent invention;

FIG. 2 is a fragmentary view of the bow and the sight; this view is to alarger scale than FIG. 1 and is of the opposite side of the bow andsight; it is the basic, albeit fully functional, sight that is shown inthis figure;

FIG. 3 is a perspective view of the bow sight; two bow sight add-ons (oraccessories) are also shown;

FIG. 3A is a perspective view of one of an array of sight pins which arecomponents of the FIG. 1 bow sight;

FIG. 3B is a horizontal section through the FIG. 3A sight pin;

FIG. 3C is a front-to-rear perspective view of an assembly of the arrayof sight pins and a sight pin support; this assembly can be removed fromand installed in the sight as a unit;

FIG. 4 is a rear view of the bow sight;

FIG. 5 is a plan view of an add-on used to adjust the torque on, and thecant of, the bow;

FIG. 6 is a perspective view of an add-on used to provide an additionalsighting pin that can be adjusted for (typically) longer range shots;

FIG. 7 is a front view of the bow sight;

FIG. 8 is a top view of the bow sight;

FIG. 9 is a perspective view of an optics unit employed in the FIG. 1bow sight; this figure shows a single one of the light transmitting, pinsight fibers; these optical fibers are housed in and coiled against theside wall of the optics unit casing;

FIG. 10 is a side view of the bow sight;

FIG. 11 is a perspective view of a component of the FIG. 5 add-onconfigured to provide for adjustment of the cant of the bow;

FIG. 12 is a fragmentary view of the bow sight included to show a levelwith a bubble that is centered for cant-free, optimum bow performance;

FIG. 13 is a vertical section through a light trap; this trap is acomponent of the optics unit of the FIG. 1 bow sight;

FIG. 14 is a perspective view showing: (a) a fragment of the bow sightincluding the optics unit, and (b) an elastomeric diaphragm mechanismthat can be employed to control the light reaching the light trap of theoptics unit;

FIG. 15 is a section through the optics unit and the elastomericdiaphragm mechanism;

FIG. 16 is a perspective view of the optics unit and an adjustableshutter mechanism that can be employed to control light reaching theoptics unit light trap; and

FIG. 17 is a view like FIG. 16 but with the shutter of the lightcontrolling mechanism adjusted to further restrict the light reachingthe light trap.

DESCRIPTION OF THE INVENTION

Referring now to the illustrations, FIGS. 1 and 2 depict a compound bow20 equipped with a fall-away arrow rest 22, an optical sight 24, and amodular stabilizer 26. Bow 20 is of conventional construction. It has ariser 28, upper and lower limbs 30 and 32, cams 34 and 36 at the farends of limbs 30 and 32, bus cables (collectively identified byreference character 38) a bow string 40, and a cable slide 42 mounted onan elongated guide 44.

Bow sight 24 includes a basic unit 46 (FIG. 2), an optional add-on oraccessory 48 (FIG. 3) which provides an additional sighting capability,and a second, also optional, add-on or accessory 50. This accessory isemployed to adjust torque and cant.

The basic unit 46 is assembled directly to the riser 28 of bow 20 (FIG.2). If the torque and cant compensation accessory 50 is added, theadd-on is assembled to the basic unit; and it is a mounting component ofthe accessory which is mounted to bow riser 28.

Referring now most particularly to FIGS. 2, 3, 4, 7, 8, and 10, thebasic bow sight 46 includes a mounting bracket 54 and a complementarycomponent 56 which functions as a housing and as a support for opticalcomponents of the sight. The two components 54 and 56 are connected by aslot-and-dovetail arrangement 58 and a threaded fastener 60. The latterclamps the two legs 62 and 64 of bracket 54 together to securelyassemble components 54 and 56.

The two legs 62 and 64 of mounting bracket 54 are attached to the riser28 of bow 20 as by the headed and threaded fasteners 66 and 68 shown inFIG. 2 to mount sight 24 to the bow.

A plate 70 located therebetween integrates the legs 62 and 64 ofmounting bracket 54 into a unitary structure.

The support/housing component 56 of bow sight 24 and the componentshoused in and supported from that component are best shown in FIGS. 2,3, 3A-3C, 4, 7, and 8.

Referring now to these figures, it was pointed out above that opticalbow sights embodying the principles of the present invention employvertically-spaced apart sight pins, each of these pins corresponding toa different bow-to-target range. The sight pins of bow sight areidentified by reference characters 74 . . . 82.

The sight pins are composed of optical fibers encased in protectivehousings that are preferably made from a metallic glass. Housingsfabricated from the preferred materials are highly resistant tocorrosion in contrast to the rust-susceptible metallic pin components ofconventional bow sights. Reference characters 82 f and 82 h in FIGS. 3Aand 3B respectively identify the optical fiber and housing ofrepresentative sight pin 82.

The sight pins 74 . . . 82 are mounted to a pin support 83, forming asight pin assembly 85 (see FIG. 3C). Assembly 85 is housed in bow sighthousing/support component 56, which also supports the casing 84 of anoptics unit 86. The assembly 85 can be removed from component 56 as aunit, which is advantageous from the viewpoints of manufacturability,serviceability, and interchangeability.

In the currently preferred sight pin assembly shown in FIG. 3C, sightpins 74 . . . 82 are installed in a selected two of three vertical slots88, 90, and 92 in sight in support 83, slot 88 being nearest the frontof the support and slot 92 being nearest its rear. Alternate pins areinstalled in slots 88 and 90, pins 74, 78, and 82 thus being installedin front slot 88 and pins 76 and 78 being installed in center slot 90.Rear slot 92 provides a protected path for the optical fibers.

The distal ends 94 . . . 102 of the sight pin optical are exposed (seeFIG. 7). It is these exposed, dot-like features of the sight pins withwhich a target is acquired. The sight pin housings are curved such thatthe optical fibers are supported from pin support (or frame 83) withsight features 94-102 facing the archer.

The array 104 of sight pins 74 . . . 82 is surrounded by a shroud 106,also to protect the pins from damage. Shroud 106 is an integralcomponent of support/housing component 56.

As shown in FIG. 2, the optical fibers of sight pins 74 . . . 82 aretrained through bow sight component 56 to the optics unit 86 of the bowsight. There, the fibers are coiled, one above the other, against theinner side 108 of optics unit casing 86. The lowermost optical fiber 109(of sight pin 82) is shown in FIG. 9.

The casing 84 of optical unit 86 has inner surfaces, described below,which are elements of a light trap 110 (FIGS. 8 and 13). The casingsupports a light collecting lens 112 directly above, and in axialalignment with, light trap 110 at the open end 114 of casing 84.

Light trap 110 is a one-piece, typically injection molded component (seeFIG. 13). The light trap includes: the inner surface 115 i of the bottomwall 115 of casing 84; the inner surface 116 i of casing side wall 116;and a conical, cored-out, integral element 117 with: (a) a uniform wallthickness “I”, (b) a base 118, (c) an apex 119, and (d) a convexexternal surface 120. The light trap may be made from any appropriatepolymer as by injection molding, for example. The light trap surfacesare coated by vapor deposition or otherwise treated to make thosesurfaces highly reflective.

Lens 112 gathers light from a field which encompasses almost an entirehemisphere. Light reaching light trap 110 through lens 112 may fall onthe external surface 120 of conical element 117, the optical fibers inand coiled against the wall 116 of casing 84, the inside surface 116 iof wall 116, or the inner surface 115 i of casing bottom wall 115. Lightthat does not directly strike the optical fibers is reflected and/orredirected onto the fibers. Therefore, essentially all of the incidentlight reaches and is loaded into the fibers; and the optical unit ishighly efficient in collecting light from the ambient surroundings andin insuring that the collected light reaches the optical fibers fortransmission through the fibers to the sighting dots 94-102 at the endsof the fibers.

Lens 112 is not a mandatory component of optical bow sights embodyingthe principles of the present invention. Even without a lens, light willfall on and into light trap 110 and be loaded into the optical fibershoused in casing 84 essentially in the manner discussed above.

Turning now primarily to FIGS. 3, 5, 8, and 10 the torque and cantadjustment accessory or add-on 50 includes two brackets, 121 and 122,connected by a vertically-extending hinge pin 124 and a mounting bracket126 which replaces the mounting bracket 54 of the basic bow sight 46.Mounting bracket 126 is assembled to bracket 122 with threaded fasteners128 and 130 (FIG. 5). The optical components of sight 46 are attached tomounting bracket 126 of accessory 50 in the same above-discussed mannerand with the same type of slot-and-dovetail coupling and threadedfastener that those components are attached_??_basic bow sight_46.

A variety of factors, such as a particular archer's grip, the balance ofthe bow, the angle of a shot, whether the archer is shooting from a treestand or other elevated position, shooting uphill, etc. causes thearcher to impose torque—that is a force pivoting the bow to the left orright about a vertical axis—on the bow. An important feature ofaccessory 50 is that it can be employed to provide compensation for thetorque. Specifically, by tightening setscrew 132, bracket 121 and theoptical components carried by that bracket, especially the sightingpins, are shifted to the right, i.e., in the direction indicated byarrow 132 in FIG. 5. Conversely, by tightening complementary setscrew136, bracket 121 is shifted in the opposite direction to move thesupported optical components to the left.

The fastener 128 securing the mount 121 of accessory 50 to opticalunit-supporting bracket 126 extends through a laterally orientedadjustment slot 138 in the support (see FIG. 11) and is threaded intomount 121.

The cant of the optical sight is adjusted by loosening fasteners 128 and130, rotating optical unit support 126 about the lower fastener untilthe bubble 140 of a level 142 mounted on the bottom of sight pin shroud106 (see FIG. 12) is centered, and then retightening fasteners 128 and130. This cant compensation adjustment can contribute significantly toaccuracy.

Turning now most particularly to FIGS. 3, 5, and 6, it was pointed outabove that the optional add-on or accessory 48 is employed to provide asight pin for a range greater than those ranges for which sight pins 74. . . 82 are intended. Accessory 48 is bolted or otherwise mounted tothe basic bow sight unit 46 in the location shown in FIGS. 3 and 4.

Accessory 48 includes a sight pin 144 mounted to a support 146, acarriage 148, and an elongated, threaded member 150 supported from androtatable in, the carriage. The threaded member is rotated by a knob 152fixed to member 150 by setscrew 154.

Carriage 148 has end plates 156 and 158. Posts 160 and 162 extendbetween and are mounted at their opposite ends to end plates 156 and158. Threaded member 150 is located equidistantly between posts 160 and162 as shown in FIG. 6.

Sight pin support 146 can be moved vertically up and down on posts 160and 162 as indicated by double-headed arrow 164 in FIG. 6. Specifically,elongated member 150 is threaded through an internally-threadedextension 166 of sighting pin support 146. Consequently, as the threadedmember 150 is rotated, the support 146 and sight pin 144 are movedvertically up and vertically down to locate the aiming point 168 at theend of the sighting pin at the height appropriate for a selectedbow-to-target range. The support is locked in place by rotating knob170.

The aiming feature 168 of sight pin 144 can be moved in and out of sightpin mount 146 to align aiming feature 168 with respect to the aimingfeatures 94 . . . 102 of sight pins 74 . . . 82. This is accomplished byloosening a screw 171 threaded into pin mount 146, shifting the sightpin into or out of support 146 as indicated by double-headed arrow 172,and then retightening the screw.

As is best shown in FIGS. 3 and 4, there is a dimple 174 at the bottomof sight pin shroud 106. This increases the distance over which thesighting end 168 of sight pin 144 can be displaced with a concomitantincrease in the ranges for which sight pin 144 can be used.

Another important feature of the present invention, employed whether ornot it is the basic sight 46 that is involved, or that sight with one orboth of the accessories 48 and 50 discussed above, is an elastomericshock and vibration damper 176. In the case of the basic unit, thedamper is mounted on that vertical wall 178 of bow sight component 56opposite mounting bracket 54 (see FIG. 2). If accessory 48 is alsopresent, damper 176 is instead mounted on that side of the accessoryopposite the basic bow sight 46 (see FIGS. 3 and 4). Damper 176 makes asignificant contribution to smooth and quiet operation of bow 20; and itreduces the possibility that shock and/or vibration might damage bowsight 24.

It is advantageous to be able to control the light which reaches lighttrap 110. This can be done with, for example, an apertured elastomericboot 182 as shown in FIGS. 14 and 15 or an adjustable shutter mechanism184 as shown in FIGS. 16 and 17.

Boot 182 has a side wall element 186 and an integral diaphragm 188 witha central aperture 190. The boot is slid down over optics unit casingside wall 116 and retained in place by friction. The size of aperture190 controls the light reaching light trap 110. By exerting a downward,arrow 192 force on the boot, the diaphragm 188 can be stretched,increasing the size of aperture 190 and, consequentially, thatproportion of incident light reaching trap 110.

The shutter mechanism 184 shown in FIGS. 15 and 16 has a cylindricalcasing 196, a stationary plate 198, and a complementary shutter 200.

Plate 198 and shutter 200 have arrays 202 and 204 of complementarytrapezoidal apertures 206 and 208. Plate is fixedly mounted in the upperend of casing 196, and shutter 200 is mounted above plate 198 forrotation about a vertical axis 210.

Rotating shutter 200 about axis 210 changes the fraction of incidentlight that can reach light trap 110 through apertures 206 and 208. Withshutter 200 rotated relative to plate 198 as shown in FIG. 16, theapertures 206 in plate 198 and the apertures 208 in shutter 200 arenearly aligned; and most of the incident light passes through aperture208 and then aperture 206 to light trap 110. When shutter 200 is rotatedabout axis 210 to the orientation shown in FIG. 17, imperforate areas209 of the shutter span the major parts of the apertures 206 in plate198. This reduces the size of the aperture 206, 208 light passages, and,consequentially, substantially reduces that fraction of the incidentlight which can reach trap 110.

Light controlling shutter mechanism 184 is assembled in any convenientmanner over the open upper end 114 of optics unit casing 84.

The light controlling mechanism shown in FIGS. 14-17 can be employedirrespective of whether or not the optics unit of the associated bowsight has a lens.

The invention may be embodied in many forms without departing from thespirit or essential characteristics of the invention. The presentembodiments are therefore to be considered in all respects asillustrative and not restrictive, the scope of the invention beingindicated by the appended claims rather than by the foregoingdescription; and all changes which come within the meaning and range ofequivalency of the claims are therefore intended to be embraced therein.

1. A sighting device which comprises: a fiber optics sighting component;and wide field optics for: collecting ambient light; and loading thefiber optics with collected light.
 2. A sighting device a defined inclaim 1 in which the wide field optics is so constructed and arrangedrelative to the fiber optics as to both side load and end load the fiberoptics.
 3. A sighting device as defined in claim 1 in which the widefield optics comprises: a light reflecting and redirecting light trap.4. A sighting device as defined in claim 3 which comprises a lightcollecting lens operatively juxtaposed to the light trap.
 5. A sightingdevice as defined in claim 3 which comprises an adjustable shutter forcontrolling the light reaching the light trap.
 6. A sighting device asdefined in claim 3 which comprises a component with an aperture ofregulatable size for controlling the light reaching the light trap.
 7. Asighting device as defined in claim 3 which comprises: optics unitcasing which has a side wall, a bottom wall, and an open end; the fiberoptics sighting component having a segment disposed in the casing andcoiled against the side wall of the casing.
 8. A sighting device asdefined in claim 7: wherein the light trap comprises a conical componentwith a substantially uniform thickness; the conical light trap componenthaving a base at the bottom wall of the optical unit casing.
 9. Asighting device as defined in claim 3 which has a highly reflectivecoating on those light trap surfaces on which light can fall.
 10. Thecombination of an optical sight and an attachable/detachable adjustablerange sighting device accessory; the optical sight comprising a supportand an array of fixedly positioned fiber optics sighting devices carriedby the support; and the accessory comprising: a displaceable fiberoptics sighting device; and a comprising mechanism for shifting theposition of the displaceable fiber optics device relative to the arrayof fixedly positioned sighting devices.
 11. A combination as defined inclaim 11 wherein the accessory comprises: a support for the displaceablefiber optics device; a carriage; the support being displaceable relativeto the carriage; and the mechanism for shifting the displaceable fiberoptics device comprising a rotatable, carriage-mounted member threadedthrough the support and an operator-manipulatable component for rotatingthe carriage-mounted member.
 12. A combination as defined in claim 11which comprises a shock/vibration damper mounted to the carriage of theaccessory.
 13. A combination as defined in claim 11 which the accessorycomprises: a sighting device mount; the adjustable sighting device beingdisplaceable in the mount relative to the array of fixedly positionedsighting devices; and the accessory further comprising auser-manipulatable component in a selected position in the mount.
 14. Acombination as defined in claim 11 in which: the sight comprises ashroud surrounding the array of fixedly positioned sighting device andthe adjustable sighting device, there being a dimple in the shroudconfigured to accommodate the adjustable range sighting device andthereby increase the range for which that sighting device can beadjusted.
 15. The combination of: a fiber optics sighting device; and ametallic glass encapsulating the sighting device.
 16. The combination ofan optical sight and an accessory offering torque and cant compensationfor a bow to which the sight is mounted: the optical sight comprising aframe and an optical unit; and the torque and cant compensationaccessory being mounted to the frame.
 17. A combination as defined inclaim 17 wherein: the torque and cant adjustment accessory comprises:first and second brackets; a vertically orientable pin hingedlyconnecting the first and second brackets; and a third mounting bracketassembled to a first of the hingedly connected brackets.
 18. Acombination as defined in claim 17 wherein the accessory comprises auser-manipulatable optical sight shifting, torque compensating mechanismfor adjusting the angular relationship between the first and second,hingedly connected accessory brackets.
 19. A combination as defined inclaim 17 wherein the torque and cant compensation accessory has a cantcompensation mechanism which comprises: a component fixing the first ofthe hingedly connected accessory brackets to the mounting bracket of theaccessory for relative pivotable movement about a horizontal axis; and auser-manipulatable component for locking the first and second accessorycomponents together in a user-selected angular relationship.
 20. Acombination as defined in claim 19 in which the optical sight has alevel bubble which is centerable by effecting relative pivotablemovement between the first and second, hingedly connected accessorybrackets.
 21. An optical sight which comprises: a fiber optics sightingdevice; a sighting device shroud; and a level bubble mounted to a lowerpart of the shroud.
 22. The combination of an optical sight and ashock/vibration damper; the optical sight comprising a frame; and thedamper being mounted to the frame.
 23. A combination as defined in claimE1 wherein the damper is fabricated from an elastomer.
 24. An opticalsight which comprises: a sighting pin; a sighting pin support; ahousing; and the sighting pin and the sighting pin support beingremovable from the housing as a single unit.